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I am using Pandas 0.8.1, and at the moment I can't change the version. If a newer version will help the problem below, please note it in a comment rather than an answer. Also, this is for a research replication project, so even though re-running a regression after appending only one new data point might be silly (if the data set is large), I still have to do it. Thanks!

In Pandas, there is a rolling option for the window_type argument to pandas.ols but it seems implicit that this requires some choice of a window size or use of the whole data sample as default. I'm looking to instead use all the data in a cumulative fashion.

I am trying to run a regression on a pandas.DataFrame that is sorted by date. For each index i, I want to run a regression using the data available from the minimum date up through the date at index i. So the window effectively grows by one on every iteration, all data is cumulatively used from the earliest observation, and no data is ever dropped out of the window.

I have written a function (below) that works with apply to perform this, but it is unacceptably slow. Instead, is there a way to use pandas.ols to directly perform this sort of cumulative regression?

Here are some more specifics about my data. I have a pandas.DataFrame containing a column of identifier, a column of dates, a column of left-hand-side values, and a column of right-hand-side values. I want to use groupby to group based on the identifier, and then perform a cumulative regression for every time period consisting of the left-hand and right-hand-side variables.

Here is the function I am able to use with apply on the identifier-grouped object:

def cumulative_ols(

    beta_dict = {}
    for dt in data_frame[date_column].unique():
        cur_df = data_frame[data_frame[date_column] <= dt]
        obs_count = cur_df[lhs_column].notnull().sum()

        if min_obs <= obs_count:
            beta = pandas.ols(
            beta = np.NaN
        beta_dict[dt] = beta

    beta_df = pandas.DataFrame(pandas.Series(beta_dict, name="FactorBeta"))
    beta_df.index.name = date_column
    return beta_df
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have you had a look at pd.expanding_apply()? –  Zelazny7 Feb 26 '13 at 19:03
That appears to be in a newer version, but I'll definitely take a look. Thanks! –  Mr. F Feb 26 '13 at 19:59
@EMS in case you cannot upgrade, expanding_apply is really just syntactic sugar. if you specify rolling_apply with the window size being the length of the entire set and min_periods equal to 1, then you get the same expanding window behavior –  Chang She Feb 27 '13 at 0:23
pandas does offer cumsum (cumulative sum) and cumprod (cumulative product) that you could apply to a series. If you can break down you reduce your function into products and sums you could achieve what you are trying to do... –  nitin Feb 27 '13 at 1:42
Yes, I actually spent most of last evening doing just this. I will post the function that I created for the univariate regression coefficient. It is unbelievable how much faster this makes it. –  Mr. F Feb 27 '13 at 13:39

1 Answer 1

up vote 0 down vote accepted

Following on the advice in the comments, I created my own function that can be used with apply and which relies on cumsum to accumulate all the individual needed terms for expressing the coefficient from an OLS univariate regression vectorially.

def cumulative_ols(
    Function to perform a cumulative OLS on a Pandas data frame. It is
    meant to be used with `apply` after grouping the data frame by categories
    and sorting by date, so that the regression below applies to the time
    series of a single category's data and the use of `cumsum` will work    
    appropriately given sorted dates. It is also assumed that the date 
    conventions of the left-hand-side and right-hand-side variables have been 
    arranged by the user to match up with any lagging conventions needed.

    This OLS is implicitly univariate and relies on the simplification to the

    Cov(x,y) ~ (1/n)*sum(x*y) - (1/n)*sum(x)*(1/n)*sum(y)
    Var(x)   ~ (1/n)*sum(x^2) - ((1/n)*sum(x))^2
    beta     ~ Cov(x,y) / Var(x)

    and the code makes a further simplification be cancelling one factor 
    of (1/n).

    Notes: one easy improvement is to change the date column to a generic sort
    column since there's no special reason the regressions need to be time-
    series specific.
    data_frame["xy"]         = (data_frame[lhs_column] * data_frame[rhs_column]).fillna(0.0)
    data_frame["x2"]         = (data_frame[rhs_column]**2).fillna(0.0)
    data_frame["yobs"]       = data_frame[lhs_column].notnull().map(int)
    data_frame["xobs"]       = data_frame[rhs_column].notnull().map(int)
    data_frame["cum_yobs"]   = data_frame["yobs"].cumsum()
    data_frame["cum_xobs"]   = data_frame["xobs"].cumsum()
    data_frame["cumsum_xy"]  = data_frame["xy"].cumsum()
    data_frame["cumsum_x2"]  = data_frame["x2"].cumsum()
    data_frame["cumsum_x"]   = data_frame[rhs_column].fillna(0.0).cumsum()
    data_frame["cumsum_y"]   = data_frame[lhs_column].fillna(0.0).cumsum()
    data_frame["cum_cov"]    = data_frame["cumsum_xy"] - (1.0/data_frame["cum_yobs"])*data_frame["cumsum_x"]*data_frame["cumsum_y"]
    data_frame["cum_x_var"]  = data_frame["cumsum_x2"] - (1.0/data_frame["cum_xobs"])*(data_frame["cumsum_x"])**2
    data_frame["FactorBeta"] = data_frame["cum_cov"]/data_frame["cum_x_var"]
    data_frame["FactorBeta"][data_frame["cum_yobs"] < min_obs] = np.NaN
    return data_frame[[date_column, "FactorBeta"]].set_index(date_column)
### End cumulative_ols

I have verified on numerous test cases that this matches the output of my former function and the output of NumPy's linalg.lstsq function. I haven't done a full benchmark on the timing, but anecdotally, it is around 50 times faster in the cases I've been working on.

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